Oven with machine learning based algorithm selection strategy

That which is claimed: 1. An oven comprising: a cooking chamber configured to receive a food product; an electromagnetic (EM) heating system configured to provide EM energy into the cooking chamber using solid state electronic components; and control electronics configured to control the EM heating system, wherein the control electronics are configured to enable user selection of a cooking program associated with cooking the food product, wherein the control electronics are configured to select a first algorithm to direct application of the EM energy to the food product, wherein the control electronics are configured to interrupt the first algorithm to perform a learning process interrupting the cooking process and to receive feedback on execution of the learning process during execution of the cooking program according to the first algorithm, wherein, responsive to detecting a trigger event during the learning process, the control electronics are configured to select a second algorithm that is different from the first algorithm to direct application of the EM energy to the food product during execution of the cooking program, wherein the first algorithm defines a first power level and a first combination of frequency and phase for application of the EM energy into the cooking chamber, and the second algorithm defines a second power level and a second combination of frequency and phase for application of the EM energy into the cooking chamber, and wherein the learning process comprises applying, during a period of the interrupting of the cooking process, a plurality of frequencies and detecting an efficiency measure relative to absorption of the frequencies into the food product, and the feedback comprises a value indicative of absorption of the frequencies associated with the learning process into the food product. 2. The oven of claim 1 , wherein the learning process is repeated multiple times during the cooking program. 3. An oven comprising: a cooking chamber configured to receive a food product; an electromagnetic (EM) heating system configured to provide EM energy into the cooking chamber using solid state electronic components; and control electronics configured to control the EM heating system, wherein the control electronics are configured to enable user selection of a cooking program associated with cooking the food product, wherein the control electronics are configured to select a first selected algorithm to direct application of the EM energy to the food product, wherein the control electronics are configured to interrupt the first algorithm to perform a learning process interrupting the cooking process and to receive feedback on execution of the learning process during execution of the cooking program according to the first selected algorithm, wherein, responsive to detecting a trigger event during the learning process, the control electronics are configured to select a second selected algorithm to direct application of the EM energy to the food product during execution of the cooking program, wherein the first selected algorithm and the second selected algorithm are different algorithm types, the first selected algorithm being selected from among a plurality of candidate algorithms of a first type, and the second selected algorithm being selected from among a plurality of candidate algorithms of a second type, and wherein the learning process comprises applying, during a period of the interrupting of the cooking process, a plurality of frequencies and detecting an efficiency measure relative to absorption of the frequencies into the food product, and the feedback comprises a value indicative of absorption of the frequencies associated with the learning process into the food product. 4. The oven of claim 3 , wherein the algorithm types are classified by a temporal association with a stage of execution of the cooking program such that the first selected algorithm is associated with a first stage of cooking the food product and the second selected algorithm is associated with a second stage of cooking the food product, and the trigger event comprises detecting a transition from the first stage to the second stage. 5. The oven of claim 3 , wherein the algorithm types are classified based on efficiency of absorption or based on uniformity of EM energy application in the cooking chamber. 6. The oven of claim 3 , wherein the algorithm types are differentiated based on one or more of cooking power, frequency parameters and phase parameters for application of the EM energy. 7. The oven of claim 1 , wherein the trigger event is indicative of a change in property of the food product, wherein the change in property includes a change in composition, change in geometry, change in orientation, or change in internal or external temperature of the food product. 8. The oven of claim 1 , wherein the trigger event comprises elapsing of a predetermined period of time. 9. The oven of claim 8 , wherein the trigger event is cyclic. 10. The oven of claim 1 , further comprising a convective heating system configured to provide heated air into the cooking chamber, wherein the control electronics are configured to control the convective heating system and the EM heating system, wherein the cooking program includes multiple stages with different cooking objectives in at least two stages, and wherein the cooking program defines different algorithms and different controls for the convective heating system for the at least two stages. 11. Control electronics configured to control an electromagnetic (EM) heating system configured to provide EM energy into a cooking chamber of an oven using solid state electronic components, the control electronics comprising a memory and processor, the memory storing a plurality of cooking programs for execution by the processor, wherein the control electronics are configured to enable user selection of a cooking program associated with cooking a food product in the cooking chamber, wherein the control electronics are configured to select a first algorithm to direct application of the EM energy to the food product, wherein the control electronics are configured to interrupt the first algorithm to perform a learning process interrupting the cooking process and to receive feedback on execution of the learning process during execution of the cooking program according to the first algorithm, wherein, responsive to detecting a trigger event during the learning process, the control electronics are configured to select a second algorithm that is different from the first algorithm to direct application of the EM energy to the food product during execution of the cooking program, wherein the first algorithm defines a first power level and a first combination of frequency and phase for application of the EM energy into the cooking chamber, and the second algorithm defines a second power level and a second combination of frequency and phase for application of the EM energy into the cooking chamber, and wherein the learning process comprises applying, during a period of the interrupting of the cooking process, a plurality of frequencies and detecting an efficiency measure relative to absorption of the frequencies into the food product, and the feedback comprises a value indicative of absorption of the frequencies associated with the learning process into the food product. 12. The control electronics of claim 11 , wherein the learning process is repeated multiple times during the cooking program. 13. The control electronics of claim 11 , wherein the first algorithm and the second algorithm are different algorithm types.